Explain the derivation of motion in a vertical circle.
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Vertical Circular motion using a string:
Suppose a body is tied to a string and rotated in vertical circle as shown
Circular Motion
Between X and Y, tension will balance out weight and hence the string will always be taut. So the velocity required to reach Y can be found out by conserving mechanical energy,
\(E_x(Energy~ at ~X) \)=\( \frac{1}{2} mu^2\)
Since the particle just reaches point Y hence Velocity at Y is zero.
\(E_y\) =\( mgR\)
Equating both we get,\( u\) = \(\sqrt{2gR}\)
Now if I want to find the minimum velocity to reach point Z, can I assume velocity to be zero at Z? The answer is no because if the velocity is zero at Z then weight will not be balanced and the string will become slack. So at Z, velocity should be such that the weight is equal to the centripetal force making tension just to be zero.
\(\frac{mv^2}{R}\) =\( mg\)——– (1)
\(E_z\) =\( mg(2R) + \frac{mv^2}{2}\)
Substituting the value of v we get
\(E_z\) = \(2.5mgR\)
Equating \(E_x\) and \(E_z\) we get,
\(u \) = \( \sqrt{5gR}\)
So now we have our critical values we can frame our cases,
Case I: \( u < \sqrt{2gR} \);
The ball will oscillate and never reach point Y.
Case II: \(\sqrt{2gR} < u < \sqrt{5gR}\)
The ball will lose contact somewhere between Y and Z and start projectile motion.
Case III: \( u > \sqrt{5gR}\)
The string will never become slack and complete the circle.
The situation is similar when the ball is tied to a rod and moved in vertical circle. The only difference is now the velocity at the top can be zero. As now the normal reaction of the rod can balance the weight at that point. Solving in a similar manner as above we get the following cases for a rod:
Case I: \( u <\sqrt{2gR}\)
The body will oscillate and not reach point Y.
Case II: \(\sqrt{2gR} < u < \sqrt{4gR} \)
The ball will oscillate and cross point Y but not reach point Z.
Case III: \(u >\sqrt{4gR}\)
The body will complete the circle.
Hope it helps you
Suppose a body is tied to a string and rotated in vertical circle as shown
Circular Motion
Between X and Y, tension will balance out weight and hence the string will always be taut. So the velocity required to reach Y can be found out by conserving mechanical energy,
\(E_x(Energy~ at ~X) \)=\( \frac{1}{2} mu^2\)
Since the particle just reaches point Y hence Velocity at Y is zero.
\(E_y\) =\( mgR\)
Equating both we get,\( u\) = \(\sqrt{2gR}\)
Now if I want to find the minimum velocity to reach point Z, can I assume velocity to be zero at Z? The answer is no because if the velocity is zero at Z then weight will not be balanced and the string will become slack. So at Z, velocity should be such that the weight is equal to the centripetal force making tension just to be zero.
\(\frac{mv^2}{R}\) =\( mg\)——– (1)
\(E_z\) =\( mg(2R) + \frac{mv^2}{2}\)
Substituting the value of v we get
\(E_z\) = \(2.5mgR\)
Equating \(E_x\) and \(E_z\) we get,
\(u \) = \( \sqrt{5gR}\)
So now we have our critical values we can frame our cases,
Case I: \( u < \sqrt{2gR} \);
The ball will oscillate and never reach point Y.
Case II: \(\sqrt{2gR} < u < \sqrt{5gR}\)
The ball will lose contact somewhere between Y and Z and start projectile motion.
Case III: \( u > \sqrt{5gR}\)
The string will never become slack and complete the circle.
The situation is similar when the ball is tied to a rod and moved in vertical circle. The only difference is now the velocity at the top can be zero. As now the normal reaction of the rod can balance the weight at that point. Solving in a similar manner as above we get the following cases for a rod:
Case I: \( u <\sqrt{2gR}\)
The body will oscillate and not reach point Y.
Case II: \(\sqrt{2gR} < u < \sqrt{4gR} \)
The ball will oscillate and cross point Y but not reach point Z.
Case III: \(u >\sqrt{4gR}\)
The body will complete the circle.
Hope it helps you
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